A PERK-FOXO1 AXIS LINKS DNA DAMAGE TO FIBROBLAST SURVIVAL IN DIFFUSE CUTANEOUS SYSTEMIC SCLEROSIS

Objective Diffuse cutaneous systemic sclerosis (dcSSc) is a life-limiting fibrotic disease. We and others have shown that dcSSc fibroblasts accumulate numerous somatic mutations associated with senescence-like features; however, the mechanism(s) enabling their survival remain unclear.

Skin biopsies were obtained from lesional tissues from dcSSc (n=10), dcSSc treated with autologous hematopoietic stem cell transplantation (ASCT, n=8) or 7 age/sex-matched healthy controls. Primary dermal fibroblasts were generated from biopsies. Spatial RNA sequencing, immunoblotting, confocal microscopy, and functional assays were used to mechanistically delineate signaling pathways linking DNA-damage with fibroblast survival.

dcSSc fibroblasts demonstrated increased pH2AX DNA double-strand-break foci yet remained apoptosis resistant. These cells displayed features of metabolic-stress remodeling, including mitochondrial hyperpolarization, increased reactive oxygen species production, and enhanced mitochondrial biogenesis. Spatial transcriptomics and subsequent biochemical analyses identified activation of a PERK/ATF4/FOXO1 axis, characterized by PERK phosphorylation, selective ATF4 translation, FOXO1 nuclear translocation, and induction of downstream antioxidant and metabolic programs. In contrast, fibroblasts from post-ASCT patients exhibited normalization of DNA-damage markers and mitochondrial parameters without ATF4/FOXO1 activation. Pharmacologic inhibition of either PERK or FOXO1 selectively restored mitochondrial-dependent apoptosis in dcSSc fibroblasts, demonstrating that this axis is required for their survival following extensive genomic injury.

dcSSc fibroblasts persist despite substantial genomic injury by engaging a PERK/ATF4/FOXO1 metabolic-adaptation program that suppresses mitochondrial-dependent apoptosis. This survival axis is not present after ASCT. Targeting PERK or FOXO1 restores apoptosis selectively in dcSSc fibroblasts, highlighting its potential use as a therapeutic target for eliminating pathogenic senescence-like fibroblasts in dcSSc. Highlights Both ex-vivo skin and in-vitro primary dermal fibroblasts derived from dcSSc patients have a higher frequency of intrinsic DNA damage signals and senescence-associated features; yet they evade mitochondrial-dependent apoptosis. Pathogenic dcSSc fibroblasts rewire their metabolism, characterized by mitochondrial hyperpolarization and elevated ROS. Spatial transcriptomics and functional analyses reveal a PERK/ATF4/FOXO1 stress-adaptation axis that drives fibroblast survival in dcSSc. This maladaptive survival program characterized by increased genotoxic stress, and mitochondrial remodelling is absent in post-ASCT fibroblasts. Targeting PERK or FOXO1 selectively sensitizes dcSSc fibroblasts to apoptosis revealing a potential promising therapeutic strategy in dcSSc. Competing Interest Statement The authors have declared no competing interest.